Virtual queue system and method

ABSTRACT

A system in accordance with present embodiments includes a plurality of wearable devices and a virtual queue control system configured to maintain respective virtual queues for respective attractions and in communication with the plurality of virtual queuing attraction stations. The virtual queue control system is configured to receive communications from the plurality of virtual queuing stations and add guests to the respective virtual queues based on the communications.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 15/460,010, entitled “Virtual Queue System and Method,” filed on Mar. 15, 2017, which claims the benefit of U.S. Provisional Application No. 62/309,306, entitled “Virtual Queue System and Method” and filed Mar. 16, 2016, the disclosures of which are incorporated herein by reference for all purposes.

BACKGROUND

The present disclosure relates generally to the field of amusement parks. More specifically, embodiments of the present disclosure relate to methods and equipment utilized to manage amusement park experiences, including queuing for attractions.

Since the early twentieth century, amusement parks have substantially grown in popularity. In order to address this increasing demand, amusement parks have been expanding by adding attractions and space. The addition of attractions (e.g., rides, restaurants, shops, and shows) generally provides an amusement park with additional capacity to handle a larger number of guests. However, the additional attractions also typically provide potential guests with an incentive to visit the amusement park. Thus, while a particular amusement park may add additional capacity, the additional capacity does not always result in an increased ability for guests to participate in park entertainment (e.g., shopping, viewing shows, riding rides) or reduced wait times for attractions. This is because there is often a corresponding increase in attendance. Further, due to operating efficiencies, it is often desirable to limit the availability of attractions during low attendance times. Thus, queuing for attractions, which may limit participation in park activities, is a perennial issue for amusement parks.

While guests have demanded bigger, better, and more elaborate attractions, they also require and expect a positive overall experience. Providing a positive overall experience for amusement park guests entails addressing certain issues related to queuing for attractions. Indeed, it is now recognized that park guests can be deterred from returning to a particular amusement park due to negative experiences with queue waiting times. Further, guests may be prevented from accessing amusement park businesses (e.g., shops) due to time spent waiting in queues. Indeed, in the past, guests have been forced to wait hours in line to experience some of the more popular attractions at an amusement park. Additionally, it is now recognized that park capacity does not always equal guest utilization of that capacity due to individual guest preferences for certain attractions over others. Accordingly, it is now recognized that it is desirable to improve amusement park queuing systems and methods.

SUMMARY

Certain embodiments commensurate in scope with the originally claimed subject matter are summarized below. These embodiments are not intended to limit the scope of the disclosure, but rather these embodiments are intended only to provide a brief summary of certain disclosed embodiments. Indeed, the present disclosure may encompass a variety of forms that may be similar to or different from the embodiments set forth below.

In accordance with one embodiment, a virtual queue system is provided that includes at least one wearable device comprising: a near field communicator; a medium range communicator; a long range communicator; and a display. The virtual queue system also includes a control system storing instructions that, when executed, cause the control system to: assign a user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on communication with the near field communicator; and communicate to one or both of the medium range communicator and the long range communicator the position assigned to the user identification within the virtual queue. The virtual queue system also includes an attraction station located proximate the attraction and comprising: a station near field communicator configured to validate access to the attraction based on confirmation of the user identification, received from the wearable device via the near field communicator, being associated with the position in the virtual queue corresponding to an entry position of the virtual queue for the attraction; and wherein one or both of the at least one wearable device or the attraction station is configured to generate a notification that the wearable device is associated with a valid access to the attraction.

In accordance with another embodiment, a virtual queue system is provided that includes at least one wearable device comprising: a near field communicator; a medium range communicator; a long range communicator; and a display. The virtual queue system also includes a control system storing instructions that, when executed, cause the control system to: assign a user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on communication with the near field communicator; and communicate to one or both of the medium range communicator and the long range communicator, the position assigned to the user identification within the virtual queue to cause the wearable device to display a countdown on the display when the position is within a predetermined time from valid entry to the attraction; and an attraction station located proximate the attraction and comprising: a station near field communicator configured to validate access to the attraction based on confirmation of the user identification, received from the wearable device via the near field communicator, being associated with the position in the virtual queue corresponding to an entry position of the virtual queue for the attraction.

In accordance with another embodiment, a virtual queue system is provided that includes at least one wearable device comprising: a near field communicator; a medium range communicator; a long range communicator; and a display. Also included is a virtual queue station comprising a near field communicator that receives a user identification from the near field communicator of the at least one wearable device; and a virtual queue control system configured to receive the user identification, wherein receiving the user identification causes the virtual queue control system to execute instructions to: assign the user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on communication with the near field communicator; and communicate to one or both of the medium range communicator and the long range communicator the position within the virtual queue assigned to the user identification and positions of other wearable devices associated with the user identification to cause the wearable device to display the position and the wearable devices associated with the user identification.

In accordance with another embodiment, a virtual queue system is provided that includes at least one wearable device comprising: a near field communicator; a medium range communicator; a long range communicator; and a display. Also included is a control system storing instructions that, when executed, cause the control system to: assign a user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on communication with the near field communicator; and communicate to one or both of the medium range communicator and the long range communicator the position assigned to the user identification within the virtual queue to the wearable device associated with the user identification; an attraction station located proximate the attraction and comprising: a station near field communicator configured to validate access to the attraction based on confirmation of the user identification, received from the wearable device via the near field communicator, being associated with the position in the virtual queue corresponding to an entry position of the virtual queue for the attraction, wherein one or both of the at least one wearable device or the attraction station is configured to generate a notification that the wearable device is associated with a valid access to the attraction; and an effects station configured to trigger a pre-programmed effect in response to receiving a signal from the near field communicator.

DRAWINGS

These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:

FIG. 1 is a schematic view of a theme park including a virtual queue system in accordance with present techniques;

FIG. 2 is a block diagram of an active wearable in accordance with present techniques; and

FIG. 3 is a block diagram of a virtual queue system in accordance with present techniques.

DETAILED DESCRIPTION

Presently disclosed embodiments facilitate virtual queuing within a theme park. A virtual queue control system as provided herein manages queuing for various attractions with the theme park to minimize or eliminate guest time spent waiting in a physical queue. In certain embodiments, a given attraction has a single virtual queue that is dynamically managed by the control system to add or remove guests, update positions in the queue, and send messages to the guests related to their queue positions. The system receives various inputs from the attractions and/or guests that are used to dynamically manage the various queues. In certain embodiments, queuing is mediated via guest devices such as active wearables (e.g., bracelets, wearable tags, necklaces or badges, etc.) that are carried by or associated with the guests and that interact with various kiosks or check-in points to permit guest to enter attraction queues. In this manner, park guests may enjoy the park without carrying paper tickets, identification, or other credentials. For example, guests at a water park may not wish to manage paper tickets that can get wet. Further, because guests wearing bathing suits have limited ability to carry identification items or handheld devices, active wearables that are compatible with water activities (e.g., waterproof) may be a more convenient way to manage queue information than a mobile device.

The present disclosure relates to a virtual queue system for a theme park (e.g., water park), wherein the virtual queue (VQ) system may include an active wearable device such as a wearable virtual queue wristband (which may be customizable with modules and decorative features). In addition, the virtual queue system may be operated in conjunction with software for allocation of or entry to a virtual queue via a “Tap-Point” module and software for ride validation via a “Tap-Point” module and other control system components. In accordance with present embodiments, interconnection (protocols and application program interface (API)) of the virtual queue system and a guest profile system may be customizable to facilitate changing purposes.

FIG. 1 is a schematic representation of a system 100 for facilitating queuing in accordance with present embodiments. The system 100 includes a computer system 102, monitoring sensors 104, a wireless communication system 106, system displays 108, active wearables 110 (e.g., a bracelet including accessible data and communication features) and other components that coordinate in accordance with present embodiments, as will be described in detail below. Specifically, it should be noted that present embodiments facilitate virtual queuing such that amusement park guests 120 can obtain a position within a virtual queue and subsequently enter a physical queue or standby loading group 122 of limited length. Present embodiments may function to limit time spent by guests 120 in physically waiting 122 and encourage participation in other areas of an amusement park, such as dining, shopping, and other entertainment venues (e.g., rides, shows). Accordingly, in one embodiment, the attraction queue is mediated entirely via the virtual queue and without physical queues.

When guests 120 arrive at a ticketing location 124 (e.g., hotel front desk, kiosk, guest service counter, park gate), the guests 120 may be provided with entry credentials (e.g., tickets or active wearables 110) among other items, such as a park map, virtual queuing instructions, and amenities instructions. Informational media (e.g., audio, video) and instructional signage may be present at all such ticketing locations 124. In some instances, guests 120 may have obtained entry credentials prior to arrival and may skip acquiring such credentials at the ticketing location 124.

Guests may enter and be provided entry into the park or a park area via an entryway 126. Specifically, as illustrated in FIG. 1, the entryway 126 may exclude a physical turnstile or similar physical traversal counting or control features that can provide an impediment to traversal of the entryway 126 when the entryway 126 is intended to be open. That is, the entryway 126 may be turnstile-less during operation. If guests 120 already have their entry credentials or an identification code or number transferred into an active wearable (“AW”) 110, the guests 120 may be provided essentially direct access to the park or park area. For example, guests 120 with properly activated AWs 110 may be allowed to walk through the entryway 126 without stopping. The credentials associated with the AW 110 being held or worn by the guests 120 will be detected and provided to a gate monitoring facility 128 that may be monitored by a park employee (e.g., a security service company). For example, this may include providing a photograph of the guest 120 (e.g., a photograph of the guest's face) passing through the entryway 126. Thus, the photograph may be used for entry privilege confirmation. In other embodiments, other features may be used, such as fingerprints or other identifying aspects (e.g., facial recognition). While certain embodiments of the disclosure are illustrated in conjunction with an AW 110, it should be understood that the disclosed techniques may be implemented with guest-associated devices that are configured to wirelessly communicate guest information, such as pocket-carried devices, handheld devices, or mobile devices. In particular embodiments, the guest-associated devices are waterproof.

If guests 120 do not have their AW 110 with them or if their AW 110 is not properly activated, they may insert ticket media 132 into a scanner 134, which facilitates transfer of information to the gate monitoring facility 128, which may include any of a number of gate monitoring systems, and informs a park employee that the guest 120 is authorized to enter the park or park area. If authorization is granted in this manner, an AW 110 may be distributed to them and a photograph of the guest's face automatically taken. For example, a photograph may be automatically taken by a camera 136 positioned proximate the entryway 126. The same camera 136 may be used for monitoring purposes as well. In other embodiments, the picture of guests 120 acquiring their AW 110 may occur in a different location. Further, in some embodiments, the guests 120 may acquire their AW 110 after progressing through the entryway 126 or prior to progressing through the entryway 126.

Wait times may be ascertained by guests by viewing displays provided at numerous locations throughout the park or park area. At the entrance of certain or all attractions, displays 108 provide the wait time for the specific attraction. For example, the water slide 142 includes a display 144 that specifically provides a wait time for that attraction. The information for each display may be provided based on information obtained by tracking AWs 110 or otherwise monitoring park areas (e.g., ride exits and entrances) with monitoring sensors 104. Further, at the exit of certain or all attractions, a display may be provided to indicate the wait times for all attractions (e.g., all attractions in the park or park area). For example, the exit area of the water slide 142 includes a display 146 that may provide wait times for all of the surrounding attractions (e.g., rides 148). The display 146 may even provide wait times for non-ride attractions, such as a wait time for a restaurant 150. The display 146 may be limited to display of wait times for attractions within a particular park area 152 (e.g., a park “village”). Also, within each park area 152, one or more wait time boards 154 (e.g., centrally located displays 108) may indicate wait times for all park attractions or attractions within the park area 152. Further still, before guests 120 place their portable devices (e.g., mobile phones) into lockers 160, mobile applications may be used via the mobile devices to ascertain wait times.

In one embodiment, the guest 120 enters the queue by walking to the attraction entry and walking through an entry portal. For example, the guest 120 may walk to the water slide 142 and walk through its attraction station 166. Once the guest 120 walks through the portal 166, the guest's AW 110 will notify him/her (e.g., via a tone, vibration, illuminator) of being added to the virtual queue. This may be achieved by detecting the AW 110 with the monitoring sensor 104 at the attraction station 166 and via aspects of the AW 110, which will be discussed further below. In another embodiment, the guest 120 may enter the virtual queue by walking to a queue entry post 168, which may indicate the name of the attraction and current wait time, and engaging the post 168 with the AW 110. This may include tapping the AW 110 against or positioning it near the post 168. The posts 168 may be located at the exit or entry of each attraction and at a central location within each park area 152 or village. In one embodiment, an individual post 168 may be associated with only one attraction such that engaging with the post 168 automatically enters the guest 120 in the virtual queue of the associated attraction, e.g., the virtual queue is entered without any guest selection between different attractions at the post 168, and tapping or engaging the post is the selection step for selecting the associated attraction. In particular embodiments, the queue entry post 168 and/or the attraction station 166, when positioned proximate an attraction, such as at an attraction entrance, may function as an entrance validator for guests already in a virtual queue.

The queue entry post 168 and the attraction station 166 may have similar functionality to one another for adding guests to a virtual queue. In addition, the attraction station 166, when positioned proximate the attraction, such as at the ride entry, may also include functionality for communicating if the guest has a valid entry position to the attraction. Validation may include near field communication with the AW 110 to access the user identification associated with the AW 110 when a guest taps in to the attraction station 166. The user identification is then communicated to a central virtual queue control system remote from the attraction station 166, which in turn accesses the real-time queue position associated with the user identification AW 110, performs rules-based filtering, and provides a validation output of a valid or an invalid position in the virtual queue for attraction entry. For example, in one example of rules-based filtering, when a guest position is at the front of the virtual queue (position 1), the guest is validated for admission. In other embodiments, when the guest position is in a front group (e.g., positions 1-10), the guest is validated for admission. In one embodiment, to encourage guests to return to the attraction for entry, all positions in the virtual queue less than a predetermined number (e.g., 10 or 5) are displayed as position 1 or are displayed on the AW 110 or otherwise indicated as being valid for entry (e.g., tone, vibration, display). In another example, when guests in positions 1−x in the virtual queue are not yet present at the attraction, and the guest is position x+1, the guest is validated. However, the value of x may be defined to be relatively small (10 or less) so that guests are not encouraged to present themselves at an attraction well in advance of gaining an entry position. Validity is indicated to the guest via near field communication to the AW 110 or one or both of a notification on the AW 110 or via a notification on the attraction station 166 (e.g., a tone or display).

Once the guest engages the queue entry post 168, the guest's AW 110 will notify the guest (e.g., via a tone, vibration, illuminator) of being added to the virtual queue. For example, the AW 110 may receive a signal to cause the displayed information on the AW 110 to change. Further, the post 168 may additionally or alternatively provide a notification of successful addition to the queue. The notification may be generated and/or communicated by a central virtual queue control system to the AW 110. In another embodiment, the notification is generated and/or communicated by the queue entry post 168. In yet another embodiment, the guest 120 may enter the virtual queue by walking to a virtual queue station, which may be implemented as a queue kiosk 172 (e.g., a single device that displays the names and wait times for all virtual queuing attractions in the park or park area). Queue kiosks 172 may be located at the entry or exit of each attraction and in a central location within each park area 152. The guest 120 selects the queue he/she wishes to enter and engages (e.g., taps) the kiosk with his/her AW 110. Once the guest 120 engages the queue kiosk 172, the guest's AW 110 will notify the guest 120 (e.g., via a tone, vibration, illuminator) of being added to the virtual queue. For example, the AW 110 may receive a signal to cause the displayed information on the AW 110 to change. Further, the kiosk 172 may additionally or alternatively provide a notification of successful addition to the queue. The notification to the AW 110 may be communicated via a near field communicator of the queue kiosk 172. Alternatively, the notification to the AW 110 may be communicated via a long or medium range communicator and may be communicated from a central control system and not from the queue kiosk 172.

In another embodiment, the guest 120 must physically go the area of a particular attraction and engage with the designated queue entry post 168 (e.g., an attraction station) for that attraction to enter the queue. That is, virtual queue entry is mediated only via the designated queue entry post (or posts) 168 that are physically co-located with the attraction. In this manner, the guest is encouraged to see an individual ride 148 and determine if the ride is of interest before entering the ride virtual queue. The central queue control system receives the communication form the post 168 or kiosk 172 and adds the guest to the appropriate virtual queue. The addition may be based on a time stamp or a counter. For example, for attractions that have multiple tap-in posts 168, the guests may be added based on the individual time stamp of the tap-in event and on a first-in basis.

In each of the embodiments discussed above, the guest's AW 110 may display the estimated return time. For example, a display on the AW 110 may provide a time (e.g., 5:02 PM) by which the guest should return to enter a loading group 122. This time may dynamically change depending on the operational factors (e.g., current ride capacity, other guests leaving the queue, guests with express (e.g., credentials to automatically jump to the front of a physical and/or virtual queue) or very important person (VIP) credentials entering the queue, inclement weather, and/or downtimes). In some embodiments, once the guest 120 has entered a virtual queue (or some limited number of virtual queues), the guest 120 can no longer enter any other virtual queue unless he/she leaves the current virtual queue, either by entering the ride or by entering a different virtual queue. For example, in one embodiment, engaging the post 168 of a ride or attraction overrides any previously existing places in a virtual queue. In this manner, the guest 120 may traverse the park and, upon noting a ride that is of greater interest or that has a shorter wait time, may simply swipe the AW 110 to enter into a new virtual queue and be automatically removed from a previous virtual queue with one action, which permits the guest 120 to minimize engagement with queue devices and enjoy the park experience.

Further, if more than one virtual queue can be entered, the difference between wait times for the available virtual queues may be set to be a sufficient time for both to be entered taking into consideration variables such as travel time between rides or attractions. The system may also artificially space multiple virtual queues to optimize the patrons' day and transit time. In one embodiment, if there is no penalty for failure to arrive at a queued attraction, aside from not being able to enter additional queues, the system may permit close-together times but may also account for a certain predicted percentage of no-shows. In another embodiment, the virtual queuing system may only be in effect if the wait time for the current attraction is greater than 10 minutes. In another embodiment, the guest 120 may be permitted to enter two virtual queues at the same time, but may only enter a single virtual queue at a time that is associated with a ride designated as a low capacity ride. For example, certain park rides may have relatively low capacity and, therefore, may develop longer virtual queues than higher capacity rides, which are capable of moving a greater number of guests through the ride in a given period of time. To control the virtual queue length of lower capacity rides, the virtual queue system as provided herein may, in certain embodiments, prevent the guest 120 from entering two low capacity ride virtual queues simultaneously. For example, when the guest 120 is already entered in a low capacity queue, engaging with the designated post 168 of a second low capacity ride may trigger a warning message displayed on a display of the post 168, e.g., “GUESTS IN LINE FOR DINOSAUR ADVENTURE MAY NOT ENTER THE LINE FOR VOLCANO RUSH. WOULD YOU LIKE TO EXIT THE LINE FOR DINOSAUR ADVENTURE TO JOIN THE LINE FOR VOLCANO RUSH?” The post 168 may then receive a guest selection of YES or NO. If the guest 120 selects no, the engagement with the post 168 of the second low capacity ride is ended. If the guest 120 selects YES, the guest 120 is added to the virtual queue of the second low capacity ride and automatically removed from the virtual queue of the first low capacity ride.

Present embodiments facilitate monitoring or waiting in the virtual queue. Guests 120 may wait in the virtual queue by experiencing instantaneous capacity attractions (e.g., a wave pool, swimming pool, splash pad, lazy river, a ride with no wait time), visiting food, beverage, or merchandising locations, or simply relaxing (e.g., resting in a lounge chair). If an attraction wait time of a virtual queue changes, this information may be provided via the communication system 106 to the AW 110, which will notify the wearing guest 120 and display the updated wait time. If a guest 120 wishes to leave a current virtual queue for another virtual queue, he/she can do so by just joining a new virtual queue as set forth in the description of the various embodiments above. If a guest leaves the park (or, in some cases, a park area) while waiting in a virtual queue, he/she is automatically removed from any virtual queues he/she is currently in. Present embodiments may establish no geographical limits within the park while waiting in a virtual queue and guests 120 may be free to go to any location and perform any task within the park.

Present embodiments encourage initiating and participating in attraction experiences. In some embodiments, the virtual queuing system 100 will notify the guest 120 prior to the guest's ride time. To determine the amount of prior notification time, the system 100 will utilize multiple factors to optimize capacity: current wait time at the attraction, current distance of the guest 120 away from the attraction, the guest's current activity, and the guest's history for arrival speeds from previous virtual queues. Once the guest is notified, the guest 120 travels to the attraction entrance and walks to the load platform, which accommodates the limited standby group 122. These factors or variables are monitored by the computer system 102 (e.g., a network of computers 302), which includes at least one processor 304 and at least one memory 306, via communication with the monitoring sensors 104. To ensure that the attraction throughput is not starved, a small standby group 122 (less than 10 minutes) may be formed prior to the load platform at each attraction. Once a guest reaches the load platform and enters the ride, he/she is removed from the current virtual queue. After experiencing the attraction, guests 120 can join another virtual queue as described above (e.g., a post, kiosk, or the like located in the exit path of the attraction).

Present embodiments also facilitate communication and management of additional data related to park management. For example, the AW 110 may also perform functions other than facilitating queue access. Specifically, the AW 110 may operate as an identification device used for cashless purchases and for validation to access controlled areas. In some embodiments, guest photographs are automatically taken while on each attraction, as triggered by the AW 110. Such photographs can be purchased by the guest 120 via an Internet portal (e.g., website, app, kiosk). Further, information may be automatically logged by the virtual queuing system 100 for data analysis. This information may include: experienced attractions (including count and order of visit), wait time for each attraction, time it takes for the guest to return to the attraction once notified, entry time into the park, exit time out of the park, amount of money spent via cashless system.

In accordance with present embodiments, guests to the theme park shall receive a wearable prior to entering the park (e.g., at the park's front gate) or at least prior to entering a portion of the park. The AW 110 will be linked to the guest's personal profile account on a database and will be configured to interact with kiosks distributed throughout the park. This interaction between the AW 110 and the kiosks will allow the guest to reserve and order items in the park. For example, a guest may reserve VQ slots, cabanas, lockers, towels, etc., using self-serve kiosks, enter and secure lockers and cabanas, and allows guests to purchase food, beverages, and items using the credit card attached to the guest profile in the database. When leaving the park, guests will be prompted to return the wearable; the returned wearable is noted to their account, the payment method is disassociated with the returned wearable, and the device is ready to be cleaned for reuse the next day.

Guests enter virtual queues at the entrances to certain attractions (e.g., rides). Guests secure entry to virtual queues by tapping the wearable at the virtual queue reservation point, kiosk, or ride entry station, which may be positioned at the ride entrances. Once secured, the wearable continues to receive updated information from the park system and wait times are updated and displayed on the guest's wearable. In some embodiments, guests can enter a maximum of two virtual queues and have the virtual queue status displayed on their wearable at any one time. In accordance with present embodiments, attractions in a park may be divided into two classes (e.g., those with a long lead time and those with shorter lead times) and the two VQs a single guest may enter at any one time may be limited to one of each type.

FIG. 2 is a schematic representation of an AW 110 in accordance with present embodiments. In the illustrated embodiment, the AW 110 includes a housing 400 in the form of a bracelet. However, in other embodiments, it may include a necklace, a headband, a ring, or other conveniently wearable item. A device 402 may be imbedded in the housing 400. The device 402 may include several separate or unified components that perform certain functions. In the illustrated embodiment, the device 402 includes a memory/identifier 404, a power module 406, a display 408, an indicator 410, a near field communicator 412, a medium range communicator 414, and a long range communicator 416. In some embodiments, these features may be limited. For example, one or both of the medium range communicator 414, and the long range communicator 416 may be receivers only. In other embodiments, the near field communicator 412, the medium range communicator 414, and the long range communicator 416 are transceivers. Further, the disclosed communicators may implemented as RFID communicators that are active or passive. In some embodiments, the memory/identifier 404 may include a simple identifier (e.g., an RFID tag), which the system 100 associates with a guest 120. In operation, the device 402 may operate to at least receive information from the system 100 to provide the user with information (e.g., a return time for a ride). Further, an indicator (e.g., a light, a vibration mechanism, or an audio feature) may provide feedback to the guest 120. Specifically, the device 402 may communicate with the system 100 via the communication system 106. In some embodiments, this may include communication from the device 402 to the system 100. However, in other embodiments, detecting the device 402 throughout the park area using the monitoring sensors 104 and analyzing such data with the system 100 may provide information related to the device 402 (e.g., wait times experienced by the user 120 associated with the device 402). In some embodiments, the AW 110 may be essentially passive and indications (e.g., confirmation sounds) may be provided by the system 100 (e.g., a speaker announcing a nickname of the wearer being entered into a particular virtual queue).

The AW 110 may be designed as a one-size fits all for average guest ages three (3) years and older. The AW 110 may include components configured to securely and wirelessly communicate, via short, medium and long ranges. For example, the AW 110 may be configured to facilitate communication with software databases (e.g., a database including guest information) and other VQ databases. Guests may be given a wearable, which is connected to VQ and park databases such that the guest's unique guest account can be accessed. The AW 110 may be configured to maintain a secure coupling with a guest, avoid water damage, and so forth when worn all day and riding dynamic body waterslides among other experiences.

The AW 110 is configured for certain functionality based on tapping, e.g., near field communication using a near field communicator 412 to communicate with a corresponding device. In one embodiment, the AW 110 may be configured to have the following functionality: ability to enter a VQ by tapping a VQ entry device (e.g., virtual queue kiosk 172); and ability to validate a guest's VQ allocation by tapping the wearable to a ride validation device (e.g., at an attraction station 166). Additional functionality of the AW 110 may include:

(1) allowing a single tap (e.g., communication with a tap-point, which may include a wireless communication device such as an RFID reader) to associate a wearable with a guest account; (2) allowing coordination with a tap-point at a kiosk to reserve a cabana, towel, lounge chair, or to access a user's profile; (3) allowing coordination with a tap-point at a point-of-sale (POS) system to purchase food, beverages or merchandise; (4) allowing coordination with a tap-point at a kiosk to reserve a locker; (5) allowing coordination with a tap-point at a locker to open a fixed locker; (6) allowing coordination with a tap-point at a locker to open a mobile locker; (7) allowing coordination with a tap-point at a special effects station to trigger pre-programmed effects (e.g., light show, water effects, selfie station); and (8) allowing a medium range reader to coordinate detection of a specific wearable with a database to inform a photo system of a user's identity.

Other functionality may be mediated by medium or long range communication, including:

(1) ability to display current VQ status on the wearable; (2) ability to receive updated VQ status wirelessly to the wearable; (3) ability to display a VQ progress indication without wireless signal; (4) allowing a medium range reader to coordinate detection of a specific wearable with a database to establish location awareness for user heat mapping and tracking; and (5) facilitating provision of alerts and messages displayed on the wearable via wireless signal, near field communication (NFC) and ultra-high frequency (UHF).

The AW 110 may include no connectors. The AW 110 may be configured to wirelessly and securely output an identification (ID) that is connected to the guest account in a park database and a VQ database. The AW 110 may be configured to display information via an electronic display. The AW 110 may be configured to transmit and receive data wirelessly, at approximate distances represented by:

1. Near field: less than five (5) centimeters (two-way proximity)—send/receive via the near field communicator 412; 2. Medium range: up to anywhere between one-half (0.5) and six (6) meters (one-way medium range)—send via the medium range communicator 414; and 3. Long range: up to anywhere between 10 to 100 meters (one way and/or two-way long range, depending upon wireless technology selected) via the long range communicator. In one embodiment, the long range communicator may be a receiver only and may not be capable of two-way communication.

The AW 110 may incorporate a battery powered system configured to provide continuous power to the wearable which exceeds 100 days of 12 hour per day normal guest usage. This requirement represents approximately one (1) year of guest usage. The AW 110 may be configured to communicate at approximately less than five (5) centimeters between wearable to tap point. Latency target associated with this may be less than 100 milliseconds. With respect to two-way proximity communication, the AW 110 may be configured to communicate wirelessly approximately at less than five (5) centimeters between the wearable to tap point. Latency target associated with this may be less than 100 milliseconds. The AW 110 may be configured to send identification information to a tap-point module, and the tap-point module will return with VQ data for a particular attraction (e.g., ride). With respect to medium range (<6 m) wireless communication, the AW 110 may communicate wirelessly at distances of approximately up to one half (0.5) to (6) meters, at speeds up to 10 km/h. With respect to long range (10-100 m) communication, the AW 110 may be configured to communicate wirelessly, at distances approximately up to 10 to 100 meters such that data is received once every ten (10) minutes. With respect to standards and protocols, the AW 110 may be configured to meet ISO 14443 specification requirements for NFC communication. Mifare, DesFire or other functional equivalent tag type compliance with all levels of ISO 14443 specifications with advanced encryption standard (AES) hardware cryptographic engine shall be used for security application. Microcontroller unit (MCU) with AES encryption engine may be used to develop enhanced authentication protocol for two-way proximity and medium range communication. Long range aspects may be configured to support an appropriate security management layer.

The AW 110 may be configured to record and store the latest VQ data received by the software system. For example, the AW 110 may be configured to store information as required by the locker system. The AW 110 may contain active and passive communication devices, which can be tapped on specific tap points within the park to communicate a wearable ID to an associated database. In one embodiment, a total latency from tap point to system response will be <250 milliseconds. The AWs 110 may also be configured to receive dynamic (wireless) updates as well as allow the system to track wearables as they pass through proximity detection portals.

The AW 110 may be configured to receive initial VQ data at a VQ allocation tap-point. Once the data is received from the initial VQ allocation tap-point, the AW 110 may receive dynamic VQ updates at a minimum rate of every ten (10) minutes, or as required to maximize battery capacity while still updating guests on a schedule that is perceived to be relevant by the guests while on the park premises.

The AW 110 may be configured to receive, store, and display information associated with up to two virtual queues (or more). For example, VQ data assigned to other guests associated with a guest may be displayed. VQ data for display on the AW 110 may include:

1. When a new VQ is added; activated at the virtual queue allocation tap-point; 2. When the wearable is activated; and 3. When a VQ time is within 15 minutes of the guest's entry window (e.g., when the guest can ride); and Fifteen (15) minutes prior to the guest's entry window, the AW 110 may start and display a countdown. The countdown may be a numeric countdown (with different time period updates) (1 sec, 1 min, 15 min, etc). The countdown update rate may adjust as the patron's ride time gets closer to the actual time (e.g. 15 min left, the clock updates every 30 seconds instead of every 5 min). The countdown may also be a graphical representation of time remaining (progress bar, hourglass, analog clock) or a color representation of time remaining (Red, Yellow, Green).

The AW 110 may be configured to interact with proximity detection devices which will enable guest location tracking by communicating with walk-through portals located throughout the park. The AW 110 may be configured to interact with proximity detection of a photo system.

The AW 110 may include a display that is readable in direct sunlight. Further, the AW 110 may be configured such that no active cooling is required, to withstand daily cleaning in a dedicated wearable washer subjected to temperatures no greater than 60° Celsius, and to withstand mild detergents (including bleach and/or iodine) for disinfecting. The AW 110 may contain self-testing firmware that cycles through a self-test and indicate that all systems are running properly or indicate that the AW 110 requires service. The AW 110 may include a battery that provides continuous power to the wearable which exceeds 100 days of 12 hours per day of normal guest usage; battery life. This requirement represents approximately one (1) year of guest usage. The AW 110 may be configured such that it has a unit life that exceeds 100 days of normal guest usage, which corresponds to approximately 1 year. The AW 110 may be configured to withstand daily inspection, cleaning, and self-testing. The AW 110 may have no internal serviceable parts. The AW 110 may be configured to function properly between 0° Celsius and 45° Celsius at 100% humidity. The AW 110 may be configured to operate after storage conditions between 0° Celsius and 60° Celsius. The AW 110 may be configured to have a minimum Submersible IP68 rating for:

1. Dust tight; and 2. Immersion in pool water to a depth of one (1) meter for 30 minutes.

The AW 110 may be configured to withstand prolonged one (1) hour exposure to temperatures of 40° Celsius environmental conditions and then be subjected to being submerged into 16° Celsius fresh water for five (5) minutes. The AW 110 may be configured to function properly as designed, with minimal cosmetic impacts, when dropped from a height of three (3) feet onto a flat concrete surface. Further, the AW 110 may be configured to continue to function properly as designed, regardless of cosmetic impact, when dropped from a height of ten (10) feet onto a flat concrete surface. The AW 110 may be configured to exhibit no mechanical defects when exposed to the equivalent of 3,000 hours of full sunlight exposure. This may be confirmed by testing in accordance with ISO 4892 UV Exposure: Plastics—Methods of Exposure to Laboratory Light Sources. The AW 110 may be configured to exhibit minimal discoloration when exposed to the equivalent of 3,000 hours of full sunlight exposure. This may be tested in accordance with ASTM E1347 Standard Practice for Color Analysis. The AW 110 may be configured to not cause skin irritation, rash, discoloration, or other negative effect when worn continuously for 12 hours. The AW 110 may include a wearable/clasp assembly, that maintains a tensile strength between five (5) and thirty (30) pounds per square inch to ensure the wearable remains attached to the guest during normal use, but will break free from the guest without causing injury when caught or snagged on an unintended obstacle. The AW 110 may be configured to continue to function properly, with minimal cosmetic impact, when subjected to a gravitational impact of two (2) Gs. This may be demonstrated by testing in accordance with ASTM D256-10 Standard Test Methods for Determining the Izod Pendulum Impact Resistance of Plastics. The AW 110 may be configured to continue to function properly, with minimal cosmetic impact, when subjected to five (5) hours of vibration at prevention of significant deterioration (PSD) of 0.02, to simulate the vibration of truck delivered shipping. This may be demonstrated by testing in accordance with SAE J1455.

The AW 110 may be configured to exhibit minimal cosmetic damage when exposed to the equivalent of five (5) days or 50 hours of normal guest use in a water park. This may be tested in accordance with ASTM D7027-13, Standard Test Method for Evaluation of Scratch Resistance of Polymeric Coatings and Plastics using an Instrumented Scratch Machine. The display of the AW 110 may be configured to exhibit minimal cosmetic damage when exposed to the equivalent of 5 days or 50 hours of use in a water park. This may be tested in accordance with ASTM F735-11, Standard Test Method for Abrasion Resistance of Transparent Plastics and Coatings Using the Oscillating Sand Method. The AW 110 may be configured to not negatively react mechanically or cosmetically when exposed to the following: fresh water, pool chlorine, soda, blood, sweat, tears, alcohol, vomit, sunscreen, insect repellant, urine, or saliva. The AW 110 may be configured to operate nominally with no adverse effects in a pool water environment with the following water quality conditions:

1. pH—range: 7.3 to 7.8; 2. Chlorine range—range: 1.0 to 10.0; 3. Total alkalinity—range: 70 to 120; 4. Calcium hardness—range: 200 to 400; and 5. Total dissolved solids—average: 1500.

A VQ tap-point, which may be implemented as an attraction station 166, virtual queue post 168, and/or virtual queue kiosk 172, as well as locker rental stations, cabana rental stations, special effects stations etc., may include hardware electrical components that are configured to provide a generic unit to be installed inside of themed enclosures. VQ tap-points may be configured to securely and wirelessly communicate with VQ wearables and other types of radio-frequency identification (RFID)/NFC chips within the HF—ISO 14443 AB range and may include wired communication to a software database. The VQ tap-point may include a RFID proximity reader, outputs for visual indication of the read LED's within the module, and outputs to connect to the software database. A VQ tap-point may include mounting features (e.g., quick disconnects and outdoor rated plugs) to allow it to be easily replaced with simple hand tools. The VQ tap-point includes features for outward visual indication of successful/unsuccessful tap/notification of exception or error display.

With respect to user experiences with VQ tap-point and VQ wearables, as guests “tap” the module (e.g., establish communication between the AW 110 and the VQ tap-point), the following may occur in certain embodiments:

1. Mode 1: Activate VQ wearable from a standby state upon guest entry to the park; 2. Mode 2: Read VQ wearable to secure a position in the virtual queue; 3. Mode 3: Read VQ wearable to enter the attraction (e.g., ride); 4. Mode 4: Read VQ wearable to check VQ reservation; 5. Mode 5: Read VQ wearable to notify guest of an exception; and 6. Mode 6: Guest is notified on the AW 110, by way of tap, that there has been an exception in their VQ. This could be a ride closure, park closure or overall error.

The VQ tap-point may be configured to receive data two ways: (1) wirelessly from the wearable at distances of less than five centimeter, and (2) via wired Ethernet connection from the software database. The VQ tap-point may contain a main tap point, as well as I/O for a supplemental tap point. Light (or other) outputs may be red, green, blue or white (RGBW) in color and may be mountable into lenses of the themed enclosures. Quantity of lights may be determined based on design of the module, i.e. two (2) eyes in a face theme, and so forth. The VQ tap-point may emit sounds via external speakers between 100 Hz-5 kHz, up to 80 dB, measured at one (1) meter, and may also contain an optional secondary output for a subwoofer. The VQ tap-point may display ride relevant information (e.g., current ride wait time, current time of day and so forth) via, for example, a full color display, and may display guest photos on another separate display; viewable by park team members. In one embodiment, the VQ tap-point may contain a microphone for automatic adjustments to the gain of the loudspeaker. The VQ tap-point may also have a hardwired Ethernet connection to the software system(s).

With respect to two-way proximity communication (distance and latency), the VQ tap-point may communicate at less than five (5) centimeters from a wearable to tap point. Target latency may be less than 100 milliseconds. The VQ tap-point may receive identification data from a VQ wearable, may send that data to the software database to determine VQ time, receive VQ time back from database, and wirelessly communicate the virtual queue time to the AW 110. The wearable ID, VQ location and VQ time may be written to the park database.

With respect to communication with other network systems, the VQ tap-point may communicate with the virtual queue database and other databases (e.g., park databases). ISO 14443 may be used for communication if NFC is the proposed solution. A multiport control unit (MCU) with AES encryption engine, along with 14443A/B NFC transponder, may be used to develop enhanced authentication protocol for two-way proximity. Regarding performance of taps in accordance with present embodiments, guests may tap their VQ wearable to the VQ tap-point hardware to enter virtual queues. Also guests may tap an attraction (e.g., ride) validation module hardware to verify an entitlement when the guest has waited in the virtual queue to physically enter the ride. The VQ tap-point may respond to the tap with appropriate sounds and lights. Total system target latency from tap to system response may be less than or equal to 250 milliseconds.

The VQ tap-point may receive updated VQ times each time a guest taps in. Further, the VQ tap-point may respond in multiple ways:

1. VQ mode—to indicate success/failure of VQ transaction. 2. Return mode—to indicate guest availability to ride; time, correct ride, and so forth.

The VQ tap-point may receive updated ride wait times to be displayed every one minute. The VQ tap-point may function properly between 0° Celsius to 45° Celsius, at 100% humidity. The VQ tap-point may survive storage conditions between −10° Celsius to 60° Celsius, at 90% humidity. With respect to ingress protection, the VQ tap-point may be designed as a NEMA Type 4. The VQ tap-point may continue to function properly when dropped from a height of three (3) feet onto a flat concrete surface. Packaging may completely protect the module from any cosmetic or functional defects when a box is dropped from a height of five (5) feet onto a flat concrete surface.

Portions of the VQ tap-point that are subjected to direct or indirect sunlight during normal use may comply with UL 746C. The VQ tap-point may continue to function properly, with minimal cosmetic impact, when subjected to 5 hours of vibration testing at PSD of 0.02; to simulate vibration of trucking/shipping. Testing may be performed in accordance with SAE J1455. The VQ tap-point may be designed such that it does not negatively react, mechanically or cosmetically, when exposed to the following conditions: fresh water, pool chlorine, soda, blood, sweat, tears, alcohol, vomit, sunscreen, insect repellant, urine, or saliva. Electro static discharge compliance of the VQ tap-point may be in accordance with IEC 61000-4-2 ESD Immunity Testing. The VQ tap-point may exhibit no mechanical and minimal cosmetic damage when exposed to the equivalent of 3,000 hours of salt spray exposure. Testing of this may be done in accordance with ASTM B117-11 Standard Practice for Operating Salt Spray (Fog) Apparatus. The VQ tap-point may comply with Restriction of Hazardous Substance Directive 2002/95/EC. Aspects of the VQ tap-point may be easily replaceable and connectable using outdoor rated pluggable connections for the following components:

1. Displays; 2. Power; 3. Speakers; 4. Network;

5. Antenna modules; and

6. Tap.

FIG. 3 is a block diagram of a virtual queue system 500 that may be implemented to manage queues in a theme park. The system 500 includes park devices 501 such as a virtual queue control system 502 in communication with one or more VQ tap-points. While the system is depicted with an embodiment including an attraction station 166 and virtual queuing station 172, it should be understood that these are examples of park devices 501 that are included in the system 500, and that other VQ tap-points or park devices 501 may be included that have similar hardware components. In addition, the functionality of the virtual queue system 500 may be distributed between the park devices 501 and the AW 110. In one embodiment, the central controller functionality is implemented via the virtual queue control system 502, which is remote from the attraction stations 166. Each park ride or attraction may be associated with one or more dedicated virtual attraction stations 166 that receive queue inputs from guests. That is, in certain embodiments, each attraction station 166 may facilitate entry into the virtual queue of only one attraction. One or both of the virtual queue control system 502 and the virtual queuing station 172 may include communications circuitry (e.g., communications circuitry 504 or 552), such as antennas, radio transceiver circuits, and signal processing hardware and/or software (e.g., hardware or software filters, A/D converters, multiplexers amplifiers), or a combination thereof, and that may be configured to communicate over wired or wireless communication paths via IR wireless communication, satellite communication, broadcast radio, Microwave radio, Bluetooth, Zigbee, Wifi, UHF, NFC, etc. Such communication may also include intermediate communications devices, such as radio towers. In one embodiment, the communication between the attraction station 166 and the virtual queue control system 502 is wired.

In addition, one or both of the virtual queue controller or control system 502 and the virtual queuing station 172 may include a memory device (e.g., memory device 508 or 510) for storing instructions executable by a processor (e.g., processor 512 or 514) to perform the methods and control actions described herein. For example, the processor 512 may execute instructions for dynamic virtual queue management based on inputs from the virtual queuing station 172 as well as data on guest entry into a ride and guest exit from a park. Additional inputs to dynamic queue management may include guest location within the park. For example, a reminder to return to the attraction may be based at least in part on the guest's location relative to the attraction, as determined via wireless signal or global positioning system (GPS) information from the guest active wearable or by a guest's last tap-in location with the virtual queuing station or other tap-in device. The system 500 may store guest locations during a park visit to create an accessible log of guest locations within the park for use in predicting guest current and future locations. If the guest is estimated to be located within a first distance or within a first zone relative to the attraction, the return reminder or message is sent to return within a first time (e.g., “YOU CAN LEAVE IN 20 MINUTES FOR VOLCANO RUSH”), which accounts for a shorter travel time to the attraction. If the guest is instead in a farther second zone or a farther estimated second distance, the return reminder or message accounts for the longer travel time by providing an earlier return time (e.g., “PLAN TO LEAVE IN 5 MINUTES FOR VOLCANO RUSH”), to account for longer walking times to the attraction. In this manner, guests at similar positions in the virtual queue but at different locations within the park are estimated to return to the attraction within the same approximate time window.

The processor may include one or more processing devices, and the memory may include one or more tangible, non-transitory, machine-readable media. By way of example, such machine-readable media can include RAM, ROM, EPROM, EEPROM, or optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to carry or store desired program code in the form of machine-executable instructions or data structures and which can be accessed by the processor or by other processor-based devices (e.g., mobile devices). For example, the virtual queue control system 502 or the virtual queuing station 172 may be accessed by an operator interface 520, e.g., a computer-based workstation or a mobile device, and/or may include an input/output interface 516 and a display (e.g., display 532).

The virtual queuing station 172 or the attraction station 166 receives signals (e.g., wireless signals, such a RF signals) from a guest AW 110. The AW 110 may, in one embodiment, tap in to the virtual queuing station (e.g., via a hand wave or via positioning the AW 110 within the reading zone of the virtual queuing station 172) where it send the signal via NFC and receives signal back and updates via NFC. Additionally, components of the system (e.g., the virtual queuing station 172 and/or the AW 110) may be actively listening for a wireless broadcast and may update the display upon receipt of the appropriate broadcast. Another option is a system where the attraction stations 166 are dumb/passive and the AW 110 reads the totem location and transmits the request through a wireless network bypassing the need to have the virtual queuing station 172 read the AW 110. These signals may, in turn, be communicated to the virtual queue control system 502 to add the guest associated with the AW 110 to the virtual queue.

While the attraction station 166 may also facilitate guest entry into a virtual queue in a manner similar to the virtual queuing station 172 and may include similar components (e.g., memory 556, processor 554, communications circuitry 552), the attraction station 166 may also be implemented as an automatic gate or reader such that the AW 110 as it passes through the attraction station 166 is automatically read and the guest associated with the AW 110 is indicated as entering the ride and, therefore, is automatically removed from the virtual queue. It should be understood that certain features of the virtual queue control system 502 may additionally or alternatively be implemented locally at the attraction station 166. Further, the attraction station 166 may also include notification devices 558 such as one or more of a display, speaker, lights, to indicate successful validation of the AW 110 for ride entry.

The virtual queue system 500 may, in certain embodiments, manage a total guest experience to ensure that an individual guest may experience a minimum number of rides or experiences per day. For example, based on the virtual queue load for various attractions, the virtual queue system 500 may permit entry into a predetermined number of queues at the beginning of the day. Alternatively, the virtual queue system 500 may dynamically present ride options to each guest at a central kiosk (e.g., queue kiosk 172, see FIG. 1). That is, while in certain embodiments, the virtual queue control system is implemented without any central queue kiosk that permits selection and virtual queue entry to multiple queues of different attractions at a single device and within a single interaction, in other embodiments one or more central kiosks may mediate entry into multiple virtual queues at once.

While only certain features of the present embodiments have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the present disclosure. Further, it should be understood that certain elements of the disclosed embodiments may be combined or exchanged with one another. 

1. A method comprising: receiving a communication from a near field communicator of at least one wearable device; assigning a user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on the communication from the at least one wearable device; updating the assigned position in the virtual queue to an updated position; outputting a position signal to one or both of a medium range communicator or a long range communicator of the at least one wearable device to cause the at least one wearable device to display a countdown on a display, wherein the position signal is indicative of the updated position in the virtual queue, and wherein the countdown is indicative of an estimated time remaining before valid entry to the attraction or the updated position in the virtual queue; validating access to the attraction at an attraction station based on the updated position in the virtual queue corresponding to an entry position of the virtual queue for the attraction; and providing instructions to cause one or both of the attraction station or the at least one wearable device to generate a notification that the at least one wearable device is associated with a valid access to the attraction based on the validating.
 2. The method of claim 1, wherein receiving the communication comprises receiving, via a queue entry post, a request from the near field communicator of the at least one wearable device to join the virtual queue.
 3. The method of claim 2, comprising outputting a request signal from the queue entry post to a central virtual queue control system in response to the communication from the at least one wearable device to cause the assigning.
 4. The method of claim 1, comprising determining that the position in the virtual queue is within a predetermined time of achieving the entry position to cause the outputting of the position signal.
 5. The method of claim 1, comprising accessing a guest profile in response to receiving the communication to obtain the user identification.
 6. The method of claim 1, wherein the long range communicator is a passive RFID transceiver.
 7. A method comprising: communicating, via a near field communicator of a wearable device, a request to join a virtual queue of an attraction to a queue entry post, wherein the request comprises an identification associated with the wearable device; receiving a signal at the wearable device that the request to join the virtual queue was granted; changing a display of the wearable device based on the received signal; receiving a position signal, via one or both of a medium range communicator or a long range communicator of the wearable device, wherein the position signal is indicative of a position in the virtual queue; and displaying a countdown on the display in response to receiving the position signal, the countdown indicative of an estimated time remaining before valid entry to the attraction or the position in the virtual queue.
 8. The method of claim 7, comprising triggering a sound effect of the wearable device based on the signal.
 9. The method of claim 7, wherein displaying the countdown on the display comprises displaying a numerical value indicative of the position of the wearable device within the virtual queue, and wherein the countdown is configured to update the numerical value based on movement within the virtual queue.
 10. The method of claim 9, wherein displaying the countdown on the display is in response to the numerical value being less than or equal to a predetermined number.
 11. The method of claim 10, comprising generating a notification on the wearable device in response to the numerical value being equal to the predetermined number.
 12. The method of claim 7, wherein displaying the countdown on the display comprises displaying the estimated time remaining based on the position of the wearable device within the virtual queue.
 13. The method of claim 12, comprising dynamically updating the estimated time remaining based on an updated position of the wearable device within the virtual queue and historical virtual queue data associated with the attraction.
 14. The method of claim 7, comprising updating the countdown on the display at a time interval determined by a countdown update rate, and wherein the countdown update rate is configured to adjust based on the estimated time remaining before valid entry to the attraction.
 15. A method, comprising: receiving a communication from a near field communicator of at least one wearable device; assigning a user identification associated with at least one wearable device to a position within a virtual queue for an attraction based on the received communication; and communicating to one or both of a medium range communicator and a long range communicator of the at least one wearable device the position within the virtual queue assigned to the user identification and other positions of other wearable devices associated with the user identification to cause the at least one wearable device to display the position and the other positions of the other wearable devices associated with the user identification.
 16. The method of claim 15, wherein the long range communicator is a passive RFID transceiver.
 17. The method of claim 15, wherein the near field communicator is an RFID transceiver.
 18. A method comprising: receiving a communication from at least one wearable device; assigning a user identification associated with the at least one wearable device to a position within a virtual queue for an attraction based on the received communication; communicating the position within the virtual queue to one or both of a medium range communicator and a long range communicator of the at least one wearable device; validating access to the attraction at an attraction station based on the position in the virtual queue corresponding to an entry position of the virtual queue for the attraction; and activating a pre-programmed special effect at a special effects station in response to receiving a signal from a communicator of the at least one wearable device.
 19. The method of claim 18, wherein the pre-programmed special effect is a light show.
 20. The method of claim 18, wherein the pre-programmed special effect is a water effect.
 21. The method of claim 18, wherein the pre-programmed special effect causes the special effects station to capture an image. 